Reverse osmosis system and automatic cycling booster pump therefor

ABSTRACT

A reverse osmosis system including a reverse osmosis filter with a reverse osmosis membrane and having an inlet port coupled to a source of feed water under predetermined pressure via a feed water inlet conduit, a product water outlet port for filtered outlet product water, and a brine outlet port for brine. A pump coupled into the feed water inlet conduit between the source of feed water and the inlet port of the filter and driven by the feed water under pressure. The pump increases the pressure of the feed water so that the reverse osmosis filter receives feed water at an increased pressure.

BACKGROUND OF THE INVENTION

This application is a division of application Ser. No. 350,521, filed May 11, 1989, now U.S. Pat. No. 5,000,845, which is a continuation in part of application Ser. No. 111,697, filed Oct. 21, 1987, now U.S. Pat. No. 4,863,924, and entitled Reverse Osmosis System And Automatic Cycling Booster Pump Therefor.

Reverse osmosis systems are commonly used for removing impurities from water, such as drinking water. A conventional reverse osmosis system includes a reverse osmosis filter having a reverse osmosis membrane. Feed water is supplied to the filter, and the filter delivers filtered product water having a reduced impurity content. Not all of the feed water supplied to the filter passes through the reverse osmosis membrane, and this unfiltered water, or brine, can be discharged to drain or a portion of it can be recycled through the filter.

To increase the throughput, i.e., the volume of product water, it is known to employ a pump to increase the pressure of the feed water supplied to the reverse osmosis filter. A conventional electric motor driven pump is used for this purpose. Motor driven pumps increase installation costs by requiring electrical wiring to the pump. In addition, they are subject to higher operational costs due to the cost of electricity and the cost of maintaining and repairing or replacing the electrical motor.

SUMMARY OF THE INVENTION

This invention overcomes these disadvantages while retaining the desirable results achieved by boosting the feed water pressure supplied to a reverse osmosis filter. With this invention, a pump driven by the feed water itself is used to increase the pressure of the feed water so that the reverse osmosis filter receives the feed water at increased pressure. No electrical wiring needs to be run to the pump.

The pump is coupled into a feed water inlet conduit between the source of feed water and the inlet port of the filter. The pump can increase the pressure of the feed water supplied to it by a desired ratio, for example, 3:1.

The pump can advantageously include a housing and a piston reciprocable in the housing to increase the pressure of the feed water. The pump of this invention also controls the flow of brine from the reverse osmosis filter to drain. In addition, the brine is used for certain pump control functions. The control of the flow of brine is accomplished by a brine valve. Means is provided for changing the position of the brine valve to control the flow of brine. With this invention, the change of position of the brine valve, e.g., from open to closed or closed to open, is used to reverse the direction of movement of the piston.

The position of the brine valve is preferably changed by a resilient coupling between the brine valve and the piston. The resilience, which can be provided by a spring, provides for closing of the brine valve after termination of the return stroke and before initiation of the next pumping stroke. Conversely, the resilient coupling provides for moving the brine valve from a partially open to a full open position after termination of the pumping stroke and before initiation of the return stroke. This resilient coupling and the sequencing of piston and brine valve movement accomplished thereby are instrumental in preventing the piston from "hanging up" at the end of a stroke. In other words, the brine valve, which acts as a reversing valve, allows the piston to complete each of its strokes before the brine valve is fully closed or fully opened. In addition, the resilience of the resilient coupling is energized by the piston in that it is piston movement which compresses or cocks a spring to store energy which is ultimately released to drive the brine valve closed or fully opened.

The housing has a cavity, and the piston reciprocates in the cavity and divides the cavity into an inlet chamber communicating with an inlet port and an outlet chamber communicating with an outlet port. To achieve a pressure boost, the piston is a differential area piston and has a first relatively large area face in the inlet chamber and a second smaller area face in the outlet chamber. This enables the fluid in the inlet chamber to drive the piston on a pumping stroke and deliver fluid at increased pressure at the outlet port.

In a preferred construction, the motion of the piston on the pumping stroke is terminated, and the piston is reversed by moving the brine valve to the open position. This enables brine to flow from the filter through the brine valve and a drain port on the housing to a reversing chamber in the housing which communicates with the drain port and the piston. This raises the pressure in the reversing chamber to assist reversing movement of the piston. In addition, a spring can be used to urge the piston on its return stroke.

In order to recharge the outlet chamber with fluid, which can be elevated to a higher pressure on the next pumping stroke, the pump includes a check valve carried by the piston. The check valve opens on the return stroke to allow fluid from the inlet chamber to flow through the check valve to the outlet chamber. The check valve opens because the opening of the brine valve provides communication between the filter and drain to thereby reduce the pressure in the outlet chamber. The check valve also constitutes a portion of the reversing means because it opens to increase the pressure in the outlet chamber over the pressure that would exist if this valve remained closed.

During the return stroke, feed water at boosted pressure is no longer being supplied to the filter. With this invention, the length of time required to accomplish the return stroke is minimized.

The brine valve is normally maintained in a closed position by differential fluid pressure. This can be accomplished, for example, by providing surfaces on the brine valve exposed to brine and fluid at drain pressure, respectively, with the brine being at the higher pressure to maintain the brine valve closed.

In addition, the surface of the brine valve exposed to brine cooperates with the housing to define a valve chamber, and a bleed passage leads to the chamber. When the valve chamber is filled with fluid, e.g., brine, it cooperates with the bleed passage to serve as a dashpot to retard movement of the valve to the open position. This is particularly compatible with the resilient coupling which tends to move the valve to the fully opened position relatively slowly.

In one form of the invention, a restricted orifice is provided in the conduit leading to drain. With this construction, the reversing chamber is always in communication with drain through the restricted orifice.

In another embodiment of the invention, the restricted orifice is eliminated. In addition, the brine valve blocks the flow of brine from the reverse osmosis filter to drain during the return stroke of the pump. With this construction, the brine valve also allows the flow of brine from the pump to drain during the pumping stroke. More specifically during the pumping stroke, the brine valve allows flow from the reversing chamber to the drain port and blocks flow from the brine inlet port to the drain port and to the reversing chamber. During the return stroke, the brine valve blocks flow from the reversing chamber to the drain port and allows flow from the brine inlet port to the reversing chamber. This embodiment has the advantage of preventing loss of water during the return stroke because, during that time, the brine valve prevents the flow of brine from the reversing chamber to drain. This keeps the ratio of brine to product water relatively constant.

The invention, together with additional features and advantages thereof, may best be understood by reference to the following description taken in connection with the accompanying illustrative drawing.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 is a schematic view partially in section illustrating a reverse osmosis system and one preferred embodiment of pump, which is driven by feed water under pressure. The piston is shown at the beginning of the pumping stroke.

FIG. 2 is a fragmentary sectional view showing a portion of FIG. 1, with the piston at the end of its pumping stroke.

FIG. 3 is a view similar to FIG. 1 illustrating a second preferred embodiment of the reverse osmosis system and pump, with the piston being illustrated at the beginning of the pumping stroke.

FIG. 4 is an enlarged, fragmentary sectional view illustrating the brine valve and the adjacent structure.

FIG. 5 is a view similar to FIG. 2 showing the second embodiment of the invention with the piston at the end of its pumping stroke.

FIG. 6 is a view similar to FIG. 4 illustrating the position of the brine valve when the piston is at the end of the pumping stroke.

DESCRIPTION OF THE PREFERRED EMBODIMENT

The drawing shows a reverse osmosis system 11 The reverse osmosis system 11 is conventional and includes a reverse osmosis membrane 17 within a housing 19. The housing 19 has an inlet port 21, a product water outlet port 23 and a brine outlet port 25.

The pump 15 includes a housing 27 having a feed water inlet port 29, a feed water outlet port 31, brine inlet port 33, a brine outlet port 35 and a drain or reversing port 37. The inlet port 29 is coupled to a source 39, such as a pump and/or a city water supply, of feed water under pressure by a conduit 41, and the outlet port 31 is coupled by a conduit 43 to the inlet port 21 of the filter 13. Together, the conduits 41 and 43 constitute an inlet conduit which extends between the source 39 of feed water and the inlet port 21 of the filter.

A conduit 44 joins the brine outlet port 25 with the brine inlet port 33. A conduit 45 joins the brine outlet port 35 with the drain port 37. A drain conduit 47 extends from the conduit 45 to drain. A restricted orifice 49 is provided in the drain conduit 47.

Although various constructions are possible, in the preferred embodiment, the housing 27 includes a main body 51, an end section 53 containing the port 31 and attached to the main body by a retaining ring 55 and an end section 57 containing the ports 33 and 35 and suitably attached to the other end of the main body 51 in any suitable manner. The end section 53 has a sleeve portion 59. The interior of the housing 27 is hollow, and a partition 61 is retained between the main body 51 and the end section 57 and divides the interior of the housing into cavities 63 and 65 on opposite sides of the partition.

A piston 67 is reciprocable in the cavity 63, and divides the cavity into an inlet chamber 69 communicating with the inlet port 29, an outlet chamber 71 communicating with the outlet port 31, and a reversing chamber 73 communicating with the drain port 37. The piston 67 is a differential area piston and has a relatively large area face 75 in the inlet chamber 69 and a smaller area face 77 in the outlet chamber 71. The piston 67 also has a reversing face 78 in the reversing chamber 73. The faces 75 and 78 are on an enlarged head 79 that sealingly slides along the peripheral wall of the inlet chamber 69 and the reversing chamber 73. The face 77 is provided, in this embodiment, as an end face of a tubular stem 81 which is sealingly slidable within the sleeve portion 59 of the end section 53. The main body 51, the sleeve portion 59 and the stem 81 are preferably coaxial. The stem 81 has an annular internal shoulder 83 adjacent the face 77. A shoulder 85 is adjacent the face 75 and, in this embodiment, is provided by an end surface of a snap ring carried by the piston 67. A coil compression spring 87 acts between the end section 53 and the head 79 of the piston 67 to urge the piston downwardly as viewed in the drawing.

A check valve 89 is carried by the piston 67 at the face 77. The stem 81 has a passage 91 extending through it, and the check valve 89 closes and opens the upper (as viewed in the drawing) end of the passage 91. The check valve 89 may be of any kind which will open when the pressure in the passage 91 is greater than the pressure in the outlet chamber 71. In the embodiment illustrated, the check valve 89 comprises an open cage 93 suitably attached to the stem 81 at the face 77 and a resilient valve element 95 loosely axially retained within the cage and on the face 77. Accordingly, when the fluid pressure in the passage 91 exceeds the fluid pressure in the outlet chamber 71, the fluid pressure in the passage 91 forces the valve element 95 upwardly as viewed in the drawing to allow fluid flow from the passage 91 to the outlet chamber 71. Conversely, when the pressure differential across the valve element is reversed, the valve element 95 is seated tightly against the face 77 to preclude flow between the outlet chamber 71 and the passage 91.

A brine valve 97 controls the flow of brine from the brine inlet port 33 to the brine outlet port 35. Although the brine valve 97 may be remote from the piston 67, in this embodiment, they are closely adjacent and within the same housing. The brine valve 97 also performs a control function for the pump 15 and, therefore, may be considered as part of the pump and within the pump housing even if it is located remotely from the piston 67.

The brine valve 97 includes a valve element 99 and a valve seat 101 of a soft, compliant material on the end section 57 of the housing 27. The valve element 99 is movable between a closed position shown in the drawing in which the valve element 99 seats on the valve seat 101 and an open position in which the valve element 99 is moved upwardly as shown in the drawing and is axially spaced from the valve seat 101 to thereby allow the flow of brine from the brine inlet port 33 to the brine outlet port 35. The valve element 99 cooperates with the housing to define a valve chamber 102 above (as viewed in FIG. 1) the valve element. A bleed passage 103 between the valve element 99 and the partition 61 allows for the flow of brine from the brine inlet port 33 into the chamber 102. Thus, the valve element 99 has a face in the chamber 102 which is exposed to brine at brine pressure and an opposite face which is exposed to fluid at drain pressure existing in the conduit 45.

The brine valve 97 is opened and closed by movement of the piston 67, and for this purpose, the brine valve and the piston are resiliently drivingly coupled together. Although this can be accomplished in different ways, in this embodiment, the connection is provided by a rod 105 coupled to the valve element 99 and extending in sealed relationship through a bore of the partition 61 into the passage 91. The coupling means also includes collars 107 and 109 slidable on the rod 105 between retaining rings 111 and 113, which are fixed on the rod 105, and a coil compression spring 115 between the collars and resiliently urging the collars away from each other. The coupling means also includes the shoulders 83 and 85.

To start up the system 11, it is only necessary to turn on the source 39 of feed water under pressure, and this can be done, for example, by opening an appropriate valve or water tap and/or turning on a pump (not shown). Of course, as is common for virtually all liquid-operated devices, it would be desirable to first bleed air from the system so that all appropriate lines and components are filled with water. Although air-bleeding techniques are well known, by way of example, the feed water from the source 39 could be turned on with the conduit 44 partly decoupled from the brine inlet port 33 to allow water to flow through and fill the chamber 71, the conduits 43 and 44 and the filter 13.

In use, feed water is supplied from the source 39 through the conduit 41 and the feed water inlet port 29 to the inlet chamber 69. As shown in the drawing, the piston 67 is at the lowermost position, and water at drain pressure acts in the reversing chamber 73 against the face 78 of the piston in conjunction with the spring 87 to tend to hold the piston in this lowermost position. Assuming that the outlet chamber 71 is charged with feed water, the feed water at inlet pressure acting over the relatively large face 75 is sufficient to move the piston 67 on a pumping stroke (upwardly as viewed in the drawing) to pressurize the water in the outlet chamber 71 and to force the pressurized feed water through the conduit 43 to the inlet port 21 of the filter 13. In so doing, the pump 15 boosts the pressure of the water at the source 39 to a higher pressure and delivers it to the filter 13. During the pumping stroke of the piston 67, the brine valve 97 remains closed due to the differential fluid pressure acting across the valve element 99 and the pressure on the upper end of the rod, and initially the spring 115 is compressed between the collars 107 and 109 to further urge the valve 97 toward the closed position. However, the spring 115 expands to move the collar 107 into engagement with the ring 111 as the pumping stroke progresses.

The reverse osmosis membrane 17 removes impurities from the water supplied to the filter 13 and delivers it to the outlet port 23 as filtered product water. Because the brine valve 97 is closed, no brine can flow from the filter 13 to drain, and consequently, the piston 67 moves on the pumping stroke to provide make up feed water at the same rate that product water is discharged at the outlet port 23.

As the piston 67 nears the end of the pumping stroke, i.e., approaches the position of FIG. 2, the shoulder 85 engages the collar 109 to compress the spring 115. This exerts an upward force on the valve element 99 and when this upward force is sufficient to overcome the valve closing force resulting from the differential pressure acting across the valve element 99, the valve element 99 is lifted off the seat 101 and is driven by the spring 115 to the fully open position after termination of the pumping stroke.

In any event, with the brine valve 97 open, brine can now flow through the conduit 44, the brine inlet port 33, the brine outlet port 35 and the conduit 45 to both the reversing chamber 73 and the orifice 49. Although the conduit 45 is open to drain via the conduit 47, the presence of the restricted orifice 49 in the conduit 47 prevents the pressure in the conduit 45 and the pressure within the reversing chamber 73 from dropping all the way to drain pressure, which may be essentially zero psig. Consequently, there is a significant pressure increase in the reversing chamber 73, and this pressure acts across the relatively large area face 78. In addition, the opening of the brine valve 97 reduces the pressure in the filter 13, the conduit 43 and the outlet chamber 71 to less than the pressure of the feed water in the inlet chamber 69. Consequently, the differential pressure acting across the check valve 89 lifts the valve element 95 to allow water to flow from the inlet chamber 69 to the outlet chamber 71. During the return stroke, the check valve 89 is held open by feed water pressure because the brine valve 97 is open so the chamber 71 communicates with drain pressure.

The effect of this is twofold. First, the opening of the check valve 89 places the face 77 essentially at the pressure of the feed water from the source 39, and this is a pressure increase relative to the pressure which existed in the outlet chamber 71 immediately prior to opening of the check valve 89. Accordingly, the increased pressure in the outlet chamber 71 and the reversing chamber 73 in conjunction with the force of the spring 87 are sufficient to move the piston 67 downwardly on its return stroke against the force of the feed water acting against the face 75.

Secondly, the opening of the check valve 89 enables the outlet chamber 71 to be recharged with feed water on the return stroke. Consequently, on the next pumping stroke, the outlet chamber 71 is charged with water which can be delivered at boosted pressure to the filter 13.

During the return stroke of the piston 67, water that cannot be contained in the chamber 71 is flushed through the filter 13 with an advantageous flushing action on the membrane 17. This is possible because, during the return stroke, the brine valve 97 is open (FIG. 2) so that there is an open flow path between the chamber 71 and the orifice 49 (FIG. 1) which leads to drain.

As the piston 67 nears the end of the return stroke, the shoulder 83 contacts the collar 107 and compresses the spring 115 to thereby provide a resilient closing force on the valve element 99. When the spring is compressed sufficiently, it generates an adequate closing force to move the valve element 99 downwardly into sealing engagement with the seat 101 to thereby close the brine valve 97. However, the spring 115 closes the valve 97 after termination of the pumping stroke. This restores the conditions which existed at the beginning of the first pumping stroke described above so that the operation can be repeated.

From the foregoing, it is apparent that movement of the piston 67 is used to open and close the brine valve 97. Also, opening of the brine valve 97 brings about termination of the pumping stroke, and closing of the brine valve 97 brings about termination of the return stroke. Reversal of movement of the piston 67 at the end of the pumping stroke is brought about by increasing the pressure within the cavity 63 and chamber 71.

The valve chamber 102 and the bleed passage 103 act like a dashpot to retard movement of the valve element 99 toward either the open or closed position. This relatively slower movement of the valve element 99 in conjunction with the spring 115 assures that the piston 67 will complete its stroke before movement of the valve element 99 is completed.

During the return stroke, feed water at boosted pressure is no longer being supplied to the filter 13. Consequently, the length of time to accomplish the return stroke and to reseat or close the brine valve 97 should be minimized. With this invention, the forces acting on the piston 67 as described above enable the return stroke to be accomplished in a minimum length of time, such as, for example, 1.5 to 2 seconds. By way of example, the pumping stroke may last 1.5 minutes, and in this event, the portion of the cycle time devoted to the return stroke and to closing of the brine valve 97 is minimal.

FIGS. 3-6 show a system 11a which is identical to the system 11 in all respects not shown or described herein. Portions of the system 11a corresponding to portions of the system 11 are designated by corresponding reference numerals followed by the letter "a."

The primary differences between the systems 11a and 11 is that the former does not have the restricted orifice 49, and the brine valve 97a controls flow among the brine port 33a, the drain port 37a and a reversing chamber port 201. In addition, the dashpot, i.e., the cavity 65 and the bleed passage 103 of the system 11 are eliminated in the system 11a, and the spring 115a is retained in a different manner.

Functionally, the primary difference between the systems 11a and 11 is that the brine valve 97a blocks flow of brine from the reversing chamber 73a to the drain port 37a during the return stroke of the piston 67a.

The brine valve 97a has a valve element 99a coupled to the rod 105a and movable therewith between the position of FIGS. 3 and 4 and the position of FIGS. 5 and 6. The valve element 99a has a passage 204 extending therethrough and is movable in a mounting member 203 which is suitably retained within the housing 27a. As shown in FIG. 3, the housing 27a may comprise housing sections 205 and 207 held together by fasteners (not shown), with the mounting member 203 captured between the housing sections. Annular seals 209, 211, 213 and 214 seal between surfaces as shown in FIG. 3. Annular, resilient valve seats 215 and 216 are retained between the mounting member 203 and the housing section 205.

The brine port 33a and the reversing chamber port 201 lead to chambers 217 and 219, respectively, and the drain port 37a leads to a drain at essentially zero pressure and to a chamber 221 above the valve seat 215. With the brine valve 97a in the position shown in FIGS. 3 and 4, the lower end of the valve element 99a engages the valve seat 216 to block communication between the chambers 217 and 219 so that the brine port 33a does not communicate with either of the ports 37a or 201. However, the valve element 99a is spaced from the valve seat 215 to provide communication between the ports 37a and 201 via openings 220 and 220' and the chamber 219 as best shown in FIG. 4.

With the brine valve 97a in the position shown in FIGS. 5 and 6, the valve element 99a is spaced from the valve seat 216 to provide communication between the brine port 33a and the reversing chamber port 201 via the chamber 217, the passage 204 in the valve element 99a, the chamber 219 and the opening 220 leading to the port 201. In addition, the valve element 99a engages the valve seat 215 to block communication between the drain port 37a and both the ports 33a and 201.

As shown in FIGS. 3 and 5, the reversing chamber port 201 is coupled via a conduit 223 to another reversing chamber port 225, which leads directly into the reversing chamber 73a. Although the ports 201 and 205 may be separate ports interconnected by a conduit as shown in the drawings, obviously the port 201 may lead directly into the reversing chamber 73a, and so functionally, the ports 201 and 225 and the conduit 223 simply serve to communicate the reversing chamber 73a with the brine valve 97a.

In this embodiment, the spring 115a is retained farther down on the piston 67a, and for this purpose, the shoulder 83a is relatively farther down on the piston than is the shoulder 83. In addition, the collar 109a is retained on an integral shoulder on the rod 105a.

The system 11a also includes a check, valve 231 in the pump 15a adjacent the inlet port 29 or in the conduit 41a between the source 39a and the pump. The check valve 31 allows flow from the source 39a to the pump 15a and prevents flow in the reverse direction. The check valve prevents the high pressure existing in the inlet chamber 69a during the return stroke from backflowing toward the source 39a, which may be a city water line.

Also, an accumulator 233 may be provided between the feed water outlet port 31a and the inlet port 21a of the filter 13a. The accumulator 233, which may be of conventional construction, allows the water under pressure from the outlet port 31a of the pump 15a to compress air in the accumulator in a known manner to thereby store energy in the compressed gas. During the return stroke, the accumulator 233 releases some of the stored energy to help maintain pressure at the filter 13 somewhat higher during the return stroke.

The operation of the system 11a is essentially identical to the operation of the system 11, except that the brine valve 97a blocks flow of brine from the reversing chamber 73a to the drain port 37a throughout the return stroke whereas, in the embodiment of FIGS. 1-2, some brine could flow to drain through the restricted orifice 49 during the return stroke. Also, the system 11a does not have a dashpot associated with the brine valve 97a, and so the function described above for the cavity 65 and the bleed passage 103 are not present in the system 11a. In other

Briefly, during the pumping stroke, the reversing chamber 73a is at atmospheric or drain pressure because it communicates with the drain port 37a while the pressure in the outlet chamber 71a is high because it is multiplied by the differential area piston 67a. Also during the pumping stroke, water from the outlet chamber 71a is forced under high pressure to and through the membrane 17a as the liquid in the reversing chamber 73a is dumped to drain, and water from the source 39a enters the inlet chamber 69a. Also, the spring is compressed. During the return stroke, the system is shut off from the drain 37a, and essentially the same high fluid pressure exists in the outlet chamber 71a, the reversing chamber 73a and the inlet chamber 69a. The energy stored in the spring 87a moves the piston 67a on the return stroke, and the water from the inlet chamber 69a moves through the check valve 89a and flows to the filter 13a to provide a flushing action through the filter and the membrane 17a. From there, the water moves to the reversing chamber 73a through the valve 99a and the conduit 223.

Of course, the brine valve 97a need not be in the housing 27a as it is only necessary that the brine valve be able to control flow from the brine outlet port 25a to the reversing chamber 73a and from the reversing chamber to drain. Although a single brine valve can accomplish these flow control functions most efficiently, the brine valve may include multiple valves, if desired.

Although an exemplary embodiment of the invention has been shown and described, many changes, modifications and substitutions may be made by one having ordinary skill in the art without necessarily departing from the spirit and scope of this invention. 

I claim:
 1. A fluid-driven pump comprising:a housing having an inlet port, an outlet port and first, second and third ports, said housing having a first cavity and said inlet port, said outlet port and said first port communicating with said cavity; a differential area piston reciprocable in said cavity and dividing the cavity into an inlet chamber communicating with the inlet port, an outlet chamber communicating with the outlet port, and a reversing chamber communicating with the first port; said piston having a first relatively large area face in said inlet chamber, a second smaller area face in the outlet chamber and a reversing face in the reversing chamber; said piston being movable on a pumping stroke during which the volume of the outlet chamber is reduced and a return stroke during which the volume of the outlet chamber is increased; a first valve for providing communication between said inlet chamber and said outlet chamber during the return stroke; said housing having a second cavity therein sealed from said inlet chamber and communicating with said first, second and third ports; a second valve in said second cavity which provides communication between the first and third ports and blocks communication between the second and third ports during the pumping stroke and provides communication between the fist and second ports and blocks communication between the first and third ports during the return stroke; and a drive connection between the piston and the second valve whereby movement of said piston operates said second valve.
 2. A fluid-driven pump as defined in claim 1 wherein said first valve includes a check valve carried by the piston and openable on the return stroke to allow fluid from the inlet chamber to enter the outlet chamber to thereby recharge the outlet chamber with fluid.
 3. A fluid-driven pump as defined in claim 1 wherein said drive connection includes resilient means for coupling the valve to The piston.
 4. A fluid-driven pump as defined in claim 1 wherein the second blocks communication between the first and second ports during the pumping stroke.
 5. A fluid-driven pump as defined in claim 1 wherein the second valve blocks communication between the second and third ports during the return stroke.
 6. A fluid-driven pump as defined in claim 5 wherein the second valve blocks communication between the first and second ports during the pumping stroke.
 7. A fluid-driven pump as defined in claim 1 wherein said second cavity and said second valve are at one end of the first cavity.
 8. A fluid-driven pump as defined in claim 7 wherein said second valve includes first and second valve seats and a valve element movable by the piston between said valve seats, said valve engaging the first valve seat during the pumping stroke to block communication between the second port and the first port and between the second port and the third port and engaging the second valve sat during the return stroke to block communication between the first and third ports and between the second and third ports. 